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Unit 1 -‐ Algebra
Chapter 3 – Polynomials Chapter 4 – Equations
MPM1D
Chapter 3 Outline
Section Subject Homework Notes
Lesson and Homework Complete (initial)
3.2 Work With Exponents
3.3a Exponent Laws
3.3b Exponent Laws
3.4 Communicate with Algebra
3.5 Collecting Like Terms
3.6 Adding and Subtracting Polynomials
3.7 The Distributive Property
Unit Performance Homework Completion: None Some Most All Days absent:______ Test Review Complete? None Some All Assignment Mark (%):______ Test Mark (%):______ Notes to yourself to help with exam preparation:
Chapter 4 Outline
Section Subject Homework Notes
Lesson and Homework Complete (initial)
4.1 Solving Simple Equations
4.2 Solving Multi-‐Step Equations
4.3a Solving Equations Involving Fractions
4.3b Solving Equations Involving Fractions
4.4 Modeling With Formulas
4.5a Modeling With Algebra
4.5b Modeling With Algebra
Unit Performance Homework Completion: None Some Most All Days absent:______ Test Review Complete? None Some All Assignment Mark (%):______ Test Mark (%):______ Notes to yourself to help with exam preparation:
Section 3.2 – Work With Exponents MPM1D Jensen Part 1: Exponents Investigation One day Sammy decided to try a new place for lunch. He went to a new restaurant called Barney’s Burgers. He loved the food so much that when he got back to school he told two of his friends. Suppose that this trend continues and every day each new customer tells two new friends at school about Barney’s Burgers. How many new customers will Barney get each day? a) Complete the chart using your knowledge of exponents
Day New Customers Expanded Form Power 1
2
2
21
2
4
2 x 2
22
3
4
b) Use this model to determine how many new customers Barney should expect on Day 7. Show your work. c) Use this model to determine how many new customers Barney should expect on Day 14. Is this answer realistic? Why or why not? d) Suppose that each new customer told three friends instead of two, and that this trend continued
i) How many new customer should Barney expect after 2 days?
ii) How many new customer should Barney expect after 4 days?
Brain Teaser: A rectangular sheet of paper measures 25 cm by 9 cm. The dimensions of a square sheet of paper with the same area are... Part 2: Exponents Repeated multiplication of the same number by itself can be expressed as a power. The number is said to be in exponential form. Express each of the following in exponential form: 1) 3×3 2) 5×5×5×5 3) (−2)(−2)(−2)(−2)(−2) 4) ℎ × ℎ × ℎ Write each expression in expanded form and then evaluate: 5) 2! 6) (−3)! 7) −3!
8) !!
!
Find the Trend Evaluate each of the following: (−2)! (−2)! (−2)! (−2)! If the base of the power is negative: -‐ and the exponent is an even # , the answer will be_________________________. -‐ and the exponent is an odd # , the answer will be__________________________. Part 3: Substitute and Evaluate Evaluate the expression for the given values of the variables: 9) 6𝑥! for 𝑥 = 5 10) 6𝑥! − 2𝑥 − 24 for 𝑥 = −6
𝑁𝑜𝑡𝑒: !𝑎𝑏!
!=𝑎!
𝑏! Therefore:
!23!
!
=
Section 3.3a – Exponent Laws MPM1D Jensen Part 1: Exponent Laws Investigation
Product Rule: Complete the following table
Describe any trends you see: Quotient Rule: Complete the following table
Describe any trends you see:
Power of a Power Rule: Complete the following table Describe any trends you see: Summary of Exponent Laws:
Part 2: Summary of Exponent Laws Product Rule When multiplying powers with the same base, keep the same _________________and __________________ the exponents. General Rule:
𝑥! ∙ 𝑥! = Quotient Rule When dividing powers with the same base, keep the same _________________and __________________ the exponents. General Rule:
𝑥! ÷ 𝑥! = Power of a Power Rule A power of a power can be written as a single power by _______________________ the exponents. General Rule:
𝑥! ! = Powers with a Rational Base When you have a single power with a rational base, you can evaluate it by applying the exponent to the ______________________________ and the _______________________________. Rule: 𝑎𝑏
!=
Part 3: Apply the Product Rule Write each product as a single power. Then, evaluate the power where possible. 1) 3! × 3! 2) 5! × 5 × 5! 3) 𝑥! 𝑥! 4) 𝑎! 𝑎! 𝑎!
5) −2 ! × −2 ! 6) !!
!× !
!
!
Part 4: Apply the Quotient Rule Write each quotient as a single power. Then, evaluate the power where possible. 7) 8! ÷ 8! 8) 4! ÷ 4÷ 4! 9) 𝑥!" ÷ 𝑥!" ÷ 𝑥!" 10) !
!
!!
11) !!.!!
!!.! ! 12) !!
!× !
!
!
!!
! 13) !!!!
!!!!
Note: An exponent of zero always gives the answer of __________ Part 5: Apply the Power of a Power Rule Write each power of a power as a single power. Then, evaluate the power where possible. 14) 3! ! 15) −2 ! !
16) !!
! ! 17) 3𝑎𝑏! !
Product Rule 𝑥! ∙ 𝑥! = 𝑥!!!
Quotient Rule 𝑥! ÷ 𝑥! = 𝑥!!!
Power of a Power Rule 𝑥! ! = 𝑥!×!
Power with a Rational Base
𝑎𝑏
!=𝑎!
𝑏!
Zero Exponent Rule 𝑥! = 1
Section 3.3b – Exponent Laws MPM1D Jensen Part 1: Do It Now Simplify and evaluate each of the following expressions: 1) 3! 3! 2) !
!"
!
3) 𝑦! ! 4) 3𝑥𝑦 − 2𝑥𝑦 Complete the following table: Part 2: Negative Exponents Any non-‐zero number raised to a negative exponent is equal to its ________________________ raised to the opposite positive power 1) 𝑥!! 2) 5!! 3) !
!
!!
Product Rule 𝑥! ∙ 𝑥! =
Quotient Rule 𝑥! ÷ 𝑥! =
Power of a Power Rule 𝑥! ! =
Power with a Rational Base
𝑎𝑏
!=
Zero Exponent Rule 𝑥! =
Negative Exponent Rule 𝑥!! =
Note: #4 is a subtraction question. Simplifying this is called ‘collecting like terms’.
You Try: a) 𝑥! ÷ 𝑥! b) !!
!
!!!
Part 3: Simplify Expressions Using Exponent Laws 4) 5𝑥! ∙ 2𝑥! 5) 2𝑎!𝑏! ∙ 3𝑎!𝑏! 6) 5𝑥! ! 7) 𝑥!𝑦! ! 8) !"!
!!!
!!!!! 9) !!!!!∙!!!!!
(!!!!)!
Hint: start by multiplying coefficients together. Then looks for powers with the same base and simplify by writing them as a single power by following the proper exponent laws.
Hint: the exponent outside of the brackets must be applied to all coefficients and variables inside the brackets using the proper exponent laws.
Hint: start by simplifying the numerator and denominator separately as much as possible using exponent laws. Then reduce the coefficients if possible and use the quotient rule to simplify powers with the same base.
10) (!!!!)!
(!!")(!!!!)
You try: a) !!
!!∙!!!!!
(!!!!)! b) (!!")
!
!!!!!
Section 3.4 – Communicate with Algebra MPM1D Jensen Brain Teaser: In the diagram, what is the area of the triangle? Part 1: Do It Now A hockey team gets 2 points for a win, 1 point for a tie, and 0 points for a loss. a) Write an equation for determining the amount of points a team has. b) If the Penguins win 54 games, tie 8, and lose 20; how many points will they get? Part 2: Terms Term: an expression formed by the product of ____________________ and or ____________________. Example of a term:
4𝑥! The number in front of the variable is called the__________________________. Identify the coefficient and the variable for the expression 4𝑥!: Coefficient: _______ Variable: _________
Practice with Terms Identify the coefficient and the variable of each term: a) Jim earns $7 per hour at his part-‐time job. If he works for 𝑥 hours, his earnings, in dollars, are 7𝑥. b) The depth, in meters, of a falling stone in a well after t seconds is −4.9𝑡! c) The area of a triangle with base b and height h is !
!𝑏ℎ
d) The area of a square with side length 𝑘 is 𝑘! Part 3: Polynomials Polynomial: an algebraic expression consisting of one or more terms connected by _____________________ or _____________________ operators. Example of a polynomial:
3𝑥! + 2𝑥 A polynomial can be classified by the number of terms it has: A _______________________________ is a polynomial with only one term. A _______________________________ is a polynomial with two terms. A _______________________________ is a polynomial with three terms. A _______________________________ is a polynomial with four terms.
Classify each polynomial by the number of terms it has:
Polynomial Number of Terms Type of Polynomial
3𝑥! + 2𝑥
−2𝑚
4𝑥! − 3𝑥𝑦 + 𝑦!
𝑎 − 2𝑏 + 𝑐 − 3
Hint: You can find the number of terms by looking for the addition and subtraction operators that separate the terms. Part 4: Degree of a Term Degree of a term: the sum of the ________________________ on the variables in a term. Example of determining the degree of a term: Term: 5𝑥!𝑦! Sum of exponents on variables: Degree of term: Find the degree of each term by adding the exponents of the variables:
Term Sum of Exponents Degree of Term
𝑥!
3𝑦!
0.7𝑢𝑣
−2𝑎!𝑏
−5
Note: -‐ a variable that appears to have no exponent actually has an exponent of _____ -‐ a constant has a degree of _____
Part 5: Degree of a Polynomial The degree of a polynomial is equal to the degree of the _______________________________________________ in the polynomial. Example: Polynomial: 3𝑥!𝑦! + 11𝑥!𝑦! + 𝑦! Highest degree term: Degree of highest-‐degree term: Degree of polynomial: Find the degree of each polynomial:
Polynomial Term with Highest Degree
Degree of Term with Highest Degree Degree of Polynomial
𝑥 + 3
5𝑥! − 2𝑥
3𝑦! + 0.2𝑦 − 1
7𝑥!𝑦! + 𝑥!𝑦
Part 6: Apply Our Knowledge Mr. Jensen works part time as a golf instructor. He earns $125 for the season, plus $20 for each children`s lesson and $30 for each adult lesson that he gives. a) Write an expression that describes Mr. Jensen's total earnings for the season. Identify the variables and what they stand for. b) If Mr. Jensen gave 8 children's lessons and 6 adult lessons, what were his total earnings?
Review of Terms _______________________________ : an expression formed by the product of numbers and/or variables _______________________________ : an algebraic expression consisting of one or more terms connected by addition or subtraction signs. _______________________________ : the sum of the exponents on the variables in a term _______________________________: equal to the degree of the highest-‐degree term in a polynomial
Section 3.5 – Collecting Like Terms MPM1D Jensen Brain Teaser: At King's, the ratio of males to females writing the Pascal Contest is 3 : 7. If there are 21 males writing the Contest, what is the total number of students writing? Part 1: Do It Now 1) What is the degree of the term: 3𝑥!𝑦𝑧 2) What is the degree of this polynomial: 3𝑎!𝑏!𝑐 + 2𝑎𝑏!𝑐! − 7𝑎𝑏𝑐! 3) Classify the polynomial from question 2) by name: Part 2: Like Terms Like Terms are terms that have the EXACT same _________________________________ with the EXACT same _________________________________. Identify the like terms in this polynomial: 3𝑥! − 5𝑥 + 2𝑥! + 3− 1+ 4𝑥 + 12𝑥! − 120
Identify the like terms in this polynomial: 5𝑥!𝑦 − 9𝑥𝑦 + 6𝑥!𝑦 + 17.3𝑥 − 2𝑥𝑦 + 4𝑥!𝑦 + 92𝑥 − 133𝑥𝑦 Part 3: Collecting Like Terms When adding/subtracting like terms, keep the variables the same, and add/subtract only the coefficients. Example: 6𝑥 + 4+ 8𝑥 + 3 = Step 1: Rearrange like terms into groups = Step 2: Add/Subtract the like terms Practice Collecting Like Terms 1) 3𝑥 + 4𝑥 2) 3𝑥! + 5𝑥! + 3 3) 2𝑏 − 𝑏 + 7− 8+ 3𝑏 4) 3𝑥! + 2− 6𝑥 + 9𝑥 − 3𝑥! 5) 2𝑥! − 3𝑦! + 𝑥𝑦 + 2𝑦! − 8𝑥! 6) 𝑎!𝑏 + 2𝑎𝑏 − 𝑎𝑏! + 2𝑎𝑏! − 3𝑎𝑏 + 𝑎!𝑏
Note: degree of terms should be in descending order (highest degree terms on the left).
Part 4: Apply our Knowledge a) Write an expression in simplest form for the perimeter of the given shape b) Evaluate the expression if 𝑥 = 5. (What is the perimeter?)
Section 3.6 – Add and Subtract Polynomials MPM1D Jensen Part 1: Do It Now The Cool Pool Company makes pools and uses the following diagram to calculate the perimeter of pool with different options: Option 1 – Bronze package (standard pool only) Option 2 – Silver package (standard pool and shallow pool) Option 3 – Gold package (all sections of the pool are included) a) In your group choose either the Bronze, Silver, or Gold package and create a simplified expression for the perimeter of your pool. b) What is the perimeter of your pool if 𝑥 = 4 Part 2: Adding Polynomials Polynomial: an algebraic expression consisting of one or more terms connected by addition or subtraction operators When adding polynomials you can simply __________________ the brackets and collect the like terms Example: 4𝑥 + 3 + 7𝑥 + 2 = Step 1: Remove the Brackets = Step 2: Rearrange like terms into groups = Step 3: Collect the like terms
Practice Adding Polynomials 1) 3𝑦 + 5 + (7𝑦 − 4) 2) 2𝑝 − 2 + (4𝑝 − 7) 3) 6𝑥 − 12 + −9𝑥 − 4 + (𝑥 + 14) 4) 5𝑥 − 4𝑦 − 1 + (−2𝑥 + 5𝑦 + 13) Part 3: Subtracting Polynomials To subtract polynomials, add the _____________________________________ (switch the signs of the terms of the polynomial being subtracted) Example: 3𝑦 + 5 − (7𝑦 − 4) The opposite of (7𝑦 − 4) is: ____________________ ∴ 3𝑦 + 5 − 7𝑦 − 4 = OR To subtract polynomials, subtract ________________________________________________ in the second polynomial. ∴ 3𝑦 + 5 − 7𝑦 − 4 =
5) 4𝑥 + 3 − (7𝑥 + 2) 6) 𝑎! − 2𝑎 + 1 − (−𝑎! − 2𝑎 − 5) 7) 3𝑥 + 𝑦 − 4𝑧 − (7𝑥 + 3𝑦 − 2𝑧) 8) 6𝑥 − 12 − −9𝑥 − 4 − (𝑥 + 14) Part 4: Apply Our Knowledge The Burgh Birds players get a $𝑥 bonus added to their base salary for every goal that they score during the playoffs. Here are the salaries and goals scored for the 3 highest scoring players on the Burg Birds during the playoffs last season. a) Write and simplify an expression for each player’s year end salary. Bardown Jensen: Wayne-‐G: Timmy: b) Write and simplify an expression for the total amount of money that the owner of the team will need to pay the three players at the end of the season. c) If 𝑥 = 25, what is the total amount of money that the owner will need to pay the three players at the end of the season?
Section 3.7 – The Distributive Property MPM1D Jensen Part 1: Do It Now Write a simplified expression for the area of the rectangle: 𝐴𝑟𝑒𝑎 𝑜𝑓 𝑟𝑒𝑐𝑡𝑎𝑛𝑔𝑙𝑒 =
Before we can simplify the expression we need to learn the distributive property!
Distributive Property When you apply the distributive property, you are getting rid of the brackets by multiplying everything in the brackets by the term in front of the brackets. Example: 5(4𝑥 + 2) = 20𝑥 + 10 Part 2: Multiply a Constant by a Polynomial Expand and simplify the following: 1) 2(5𝑥 + 3) 2) −2(7𝑥 − 4)
Remember: 𝐴𝑟𝑒𝑎 = 𝑙𝑒𝑛𝑔𝑡ℎ × 𝑤𝑖𝑑𝑡ℎ
To apply the distributive property, I must multiply both terms in the bracket by 5.
Note: Make sure to include the negative sign when distributing the -‐2. Follow integer rules for multiplication.
Note: You can also apply the distributive property to trinomials.
Remember: You can collect like terms! Like terms have identical variables (same letters and exponents)
3) −3(2𝑥! − 5𝑥 + 4) 4) 2 6𝑚 − 3 + 3(16+ 4𝑚) Part 3: Apply Our Knowledge Write an expression for the area of the rectangle in expanded form: What is the area of the rectangle if 𝑥 = 5 cm? Part 4: Distribute Variables Example: 𝑥(𝑥! − 3) = 𝑥! − 3𝑥 6) 𝑥(𝑥 − 3) 7) – 𝑥(7𝑥 − 4) 8) −3𝑥(2𝑥! − 5𝑥 + 4) 9) 3𝑚 𝑚 − 5 − (2𝑚! −𝑚)
Remember the exponent laws: 𝑥(𝑥!) = 𝑥!!! = 𝑥!
For this question you can multiply the second polynomial by -‐1 or use the properties for subtracting polynomials; both give the same result!
10) !!2𝑤 − 6 − !
!(9𝑤 − 6)
Part 5: Nested Brackets If there is a bracket inside of a bracket, simplify the inner most brackets first and then work your way out. 11) 3[2+ 5 2𝑘 − 1 ]
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